EP0144342A1

EP0144342A1 - Ore irradiator.

Info

Publication number: EP0144342A1
Application number: EP84901606A
Authority: EP
Inventors: Colin Geoffrey Clayton
Original assignee: UK Atomic Energy Authority
Current assignee: UK Atomic Energy Authority
Priority date: 1983-04-22
Filing date: 1984-04-18
Publication date: 1985-06-19
Also published as: EP0144342B1; BR8406807A; JPS60501128A; US4898709A; CA1218474A; GB8310991D0; WO1984004393A1; FI844766L; JPS6342226B2; FI844766A0; ZA842953B; AU561481B2; DE3464522D1; AU2861784A

Abstract

Un appareil d'irradiation (4) permet d'irradier des morceaux de minerai pour détecter la présence d'or dans les morceaux par analyse de l'activation des neutrons. L'appareil d'irradiation (4) se compose d'un réseau à assemblage serré de trois conduites cylindriques internes (14) et de trois conduites cylindriques externes (12) au travers desquelles on fait passer les morceaux de minerai, trois sources de neutrons (16) étant disposées dans les interstices entre les conduites internes (14) et les conduites externes (12) pour irradier les conduites (12, 14) et activer toute particule d'or suivant la réaction 197Au (n, n'gamma)197mAu. Chaque conduite interne (14) est ainsi adjacente à deux sources de neutrons (16), et présente une section transversale plus grande que les autres conduites (12).An irradiation device (4) makes it possible to irradiate pieces of ore to detect the presence of gold in the pieces by analyzing the activation of the neutrons. The irradiation apparatus (4) consists of a tightly assembled network of three internal cylindrical conduits (14) and three external cylindrical conduits (12) through which the pieces of ore are passed, three sources of neutrons (16) being arranged in the interstices between the internal pipes (14) and the external pipes (12) to irradiate the pipes (12, 14) and activate any particle of gold according to the reaction 197Au (n, n'gamma) 197mAu . Each internal pipe (14) is thus adjacent to two neutron sources (16), and has a larger cross section than the other pipes (12).

Description

Ore Irradiator

This invention relates to apparatus for detecting the presence of a selected substance in ores by neutron activation analysis, for example the gold content of gold-bearing ores.

A practical gold ore sorting plant needs to be able to process several tonnes of ore an hour, and hence must use a rapid analytical technique. A suitable technique is neutron activation analysis using the reaction ¹⁹⁷ Au (n, n' γ ) ^197mAu to activate gold present in a lump of ore, the ^197mAu nuclides so produced decaying with a half-life of about 7.8 seconds, with the emission of γ -rays of energy 279 keV. British Patent Specifications Nos. 2 055 465A and 2 101 304A (U.S. Patent No. 4 340 443, and U.S. Serial No. 383 686 filed 27 May 1982, respectively) which are incorporated by reference herein, describe apparatus for sorting gold bearing ores in which lumps of ore are activated by the above reaction, the γ -rays emitted subsequently being detected and analysed to assess the gold content of the ores.

According to the present invention there is provided an irradiator for irradiating lumps of ore for detecting the presence of a selected substance in the lumps, the irradiator comprising a plurality of ducts arranged in a close-packed array, means for rotating each duct about its longitudinal axis, and a plurality of neutron sources for irradiating the ducts and located in spaces between the ducts so that each duct is adjacent to at least one source.

Preferably, the ducts are arranged to be upright in use. Each neutron source may comprise a target arranged to be bombarded by a high energy particle beam, the particle beams being incident on the targets in a direction parallel to the longitudinal axes of the ducts and provided by a common particle accelerator.

Some of the ducts are desirably adjacent to and thereby irradiated by more than one neutron source, and these ducts may be of greater cross-sectional area than those ducts which are adjacent to only one neutron source.

Conveniently, the number of ducts is six and the number of neutron sources three, and the longitudinal axes of the ducts may be located approximately at the vertices of an equilateral triangle and at the mid-points of the sides of the triangle.

In the preferred embodiment of the invention for detecting the presence of gold in gold-bearing ores, each neutron source comprises a lithium target arranged to be bombarded by a beam of high energy protons so as to produce neutrons of energy between 0.5 and 3.0 MeV.

The invention will now be further described by way of example only and with reference to the accompanying drawings, in which:

Figure 1 is a flow diagram of a gold ore sorting apparatus including an irradiator according to the invention; and

Figure 2 is a cross-sectional representation of the irradiator of Figure 1.

Referring to Figure 1, a gold ore sorting apparatus comprises a rock crusher and classifier 2 to which mined ore is supplied, in which the ore is crushed into lumps and divided into two streams of lumps corresponding to mesh sizes of about 80mm and 60mm respectively, while lumps smaller than mesh size about 35mm are rejected. Both streams of lumps are passed through an irradiator 4 to be described in more detail later, and then all the lumps are caused to pass a γ -ray detector assembly 6 arranged to detect γ -rays having an energy of 279 keV arising from the decay of ^197mAu nuclides and so signifying the presence of gold in the lumps of ore. Each lump of ore is interrogated individually by the detector assembly 6 to establish whether its gold content lies above or below some predetermined concentration. The critical concentration is typically in the range 0.5 to 5 parts per million (ppm), and might for example be set at 1 ppm. Each lump of ore is then passed into a sorter 8 arranged by means of a cable 7 to respond to signals from the detector assembly 6, and to sort each lump of ore into one of two outlet streams depending on whether the gold concentration in the lump lies above or below the predetermined concentration.

The crusher and classifier 2 and the sorter 8 may be of types well known in the art, while the detector assembly 6 may be as described more fully in the aforementioned specifications to which reference may be made, the crusher and classifier 2, the sorter 8 and the detector assembly 6 not being the subject of the invention.

Referring to Figure 2, the irradiator 4 comprises a close packed array of three outer tubular steel cylinders 12 and three inner tubular steel cylinders 14, with their longitudinal axes upright, the axes of the three outer cylinders 12 being at the corners of a notional equilateral triangle, and the axes of the three inner cylinders 14 being near the mid points of the sides of the triangle. Each of the inner cylinders 14 is of internal diameter 32cm and each of the outer cylinders 12 is of internal diameter 26cm. The outer cylinders 12 and the inner cylinders 14, although close packed, are not contiguous, and each is caused to rotate about its longitudinal axis in a clockwise sense by a drive from an electric motor (not shown).

The outer cylinders 12 and the inner cylinders 14 adjacent thereto define between them three spaces 15 in which respective neutron sources 16 are situated in a horizontal plane at an intermediate position along the length of the outer cylinders 12 and the inner cylinders 14. Each neutron source 16 comprises a lithium target, at the end of a respective evacuated flight tube (not shown), the three flight tubes emerging via a beam splitter (not shown) from a single proton accelerator (not shown), and the end portion of each flight tube extending parallel to the axes of the cylinders 12, 14. Flight tubes, beam splitters and accelerators are well known in the art, and further details will not be given.

The outer cylinders 12, the inner cylinders 14 and the neutron sources 16 are located within a cylindrical chamber 20 defined by a concrete radiation shield 22 which is sufficiently thick to be substantially impervious to γ -rays and to neutrons and far enough away so as not to generate an intense field of interfering low energy neutrons. A typical distance is 100cm.

In operation of the irradiator 4, the streams of ore from the crusher and classifier 2 (see Figure 1) are passed through the outer cylinders 12 and the inner cylinders 14, the stream of larger lumps of ore being passed through the inner cylinders 14. The accelerator is energised to cause a beam of protons of energy 4.5 MeV to bombard each lithium target, the proton beam being moved around the surface of the target to avoid localized overheating. Fast neutrons of energy between about 0.5 MeV and 2.8 MeV are produced by the reaction 7 Li (P, n) 7 Be, and irradiate 3 4 the lumps of ore in the adjacent outer cylinders 12 and inner cylinders 14. The neutron flux decreases with distance from the sources 16, hence to provide as uniform an irradiation of the ore lumps as possible the outer cylinders 12 and the inner cylinders 14 are rotated about their respective longitudinal axes so that each lump of ore traverses the high intensity region of the neutron flux from one of the sources 16 twice, as it passes along the cylinder 12, 14.

If any gold is present in a lump of ore it will be activated by the reaction ¹⁹⁷Au (n, n' γ ) ^197mAu the cross-section for which is a maximum for neutrons of energy about 2.5 MeV. Fast neutrons of energy below 2.8 MeV are capable of bringing about this activation, but have insufficient energy to bring about activation by (n, p) reactions of other elements which are likely to be present in the ore, such as aluminium and silicon.

The irradiator 4 enables a greater throughput of ore to be irradiated than the irradiators described in the aforementioned specifications and also enables larger lumps of ore to be irradiated. This is because each of the sources 16 can produce a total neutron flux of about 10¹² neutrons/second, about ten times greater than the neutron fluxes available from the sources described in the aforementioned specifications, and because the use of two sources 16 to irradiate each of the larger, inner cylinders 14 means that substantially uniform irradiation and activation of all the lumps of ore in each inner cylinder 14 is achievable with cylinders of larger diameter than can be satisfactorily irradiated with a single neutron source.

It will be appreciated that the uniformity of irradiation of lumps of ore in the three inner cylinders 14 may be still further improved by the provision of a fourth neutron source at the position marked A in Figure 2 between the three inner cylinders 14.

The inner cylinders 14 and the outer cylinders 12 may have diameters differing from the values given. However to avoid interfering excitations brought about by intermediate energy neutrons all the cylinders are preferably of diameter less than about 50cm, while to ensure uniform irradiation of the lumps of ore those cylinders which are adjacent to only one neutron source are preferably of diameter less than 35cm. It will also be appreciated that the number of cylinders need not be six, and that they may be disposed in a different close-packed array.

It will be understood that although the sources 16 have been described as comprising lithium targets onto which generally vertical beams of protons are incident from a common accelerator, each target may be bombarded by a particle beam from a separate accelerator, and if desired the beams may be incident in generally horizontal directions through the spaces between the adjacent outer cylinders 12 and inner cylinders 14. It will also be understood that alternative neutron sources such as those utilizing a D (D, n) ³He reaction may be used as long as the neutrons produced are of energies less than about 3 MeV.

Claims

Claims :

1. An irradiator for irradiating lumps of ore for detecting the presence of a selected substance in the lumps, the irradiator comprising a plurality of ducts (12, 14), and means for rotating each duct about its longitudinal axis, characterised in that the ducts are arranged in a close-packed array so as to define spaces (15) between the ducts, and that a plurality of neutron sources (16) for irradiating the ducts are located in the spaces between the ducts so that each duct is adjacent to at least one source.

2. An irradiator as claimed in Claim 1 wherein the ducts (12, 14) are arranged to be upright in use, so that gravity causes the lumps to move down the ducts.

3. An irradiator as claimed in Claim 1 wherein each neutron source (16) comprises a target arranged to be bombarded by a high energy particle beam.

4. An irradiator as claimed in Claim 3 comprising a particle accelerator, and a plurality of beam tubes extending substantially parallel to the longitudinal axes of the ducts to carry the particle beams from the particle generator to the targets.

5. An irradiator as claimed in Claim 1 wherein at least some of the ducts (12, 14) are adjacent to, and so in use irradiated by, more than one neutron source (16).

6. An irradiator as claimed in Claim 5 wherein some of the ducts (14) are adjacent to more than one source (16), the other ducts (12) are adjacent to one source (16), and the former ducts (14) are of greater cross-sectional area than the latter.

7. An irradiator as claimed in Claim 1 wherein the number of ducts is six and the longitudinal axes of the ducts are located at least approximately at the vertices of an. equilateral triangle and at the mid-points of the sides of the triangle, and the irradiator includes three neutron sources.

8. An irradiator as claimed in Claim 1 also including a radiation shield (22) surrounding the ducts and spaced away from them.

9. An irradiator as claimed in Claim 1 wherein the ducts are of width about 30 cm.

10. An irradiator as claimed in Claim 3, suitable for detecting the presence of gold in gold-bearing ores, wherein the target is of lithium and the particle beam is of high energy protons of such an energy as to produce neutrons of energy between 0.5 and 3.0 MeV.

11. An ore sorting apparatus incorporating an irradiator as claimed in any one of the preceding claims.